|Publication number||US20100252115 A1|
|Application number||US 12/751,272|
|Publication date||Oct 7, 2010|
|Filing date||Mar 31, 2010|
|Priority date||Apr 1, 2009|
|Also published as||US8087640|
|Publication number||12751272, 751272, US 2010/0252115 A1, US 2010/252115 A1, US 20100252115 A1, US 20100252115A1, US 2010252115 A1, US 2010252115A1, US-A1-20100252115, US-A1-2010252115, US2010/0252115A1, US2010/252115A1, US20100252115 A1, US20100252115A1, US2010252115 A1, US2010252115A1|
|Original Assignee||Luis Bassols|
|Export Citation||BiBTeX, EndNote, RefMan|
|Referenced by (1), Classifications (14), Legal Events (1)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This claims the benefit of non-provisional of 61/165,887 filed Apr. 1, 2009, incorporated herein by reference.
This relates to valves, for example faucet valves, and also for example valves that do not require manual operation.
2. Related Art
Water usage continues to be an issue in many countries, and government agencies and private parties continue to promote conservation measures. Hygiene is also an issue requiring appropriate handwashing and other measures. One device that addresses both issues is an infrared sensor incorporated into faucets sensing demand for water, and supplying water upon demand without requiring handling of faucet valves. However, such sensors require special retrofit or replacement of existing faucets and appropriate electronics to delay shutting off the water until a selected time has elapsed. While conservation is promoted, there may be excess water consumption with such devices if the time delay is too long. Additionally, such devices typically lack an option for adjusting water temperature.
Manual devices requiring activation of a valve and having a spring or other bias for returning the valve to the closed position may include complicated configurations, provide insufficient water flow or pressure, or be difficult to assemble or maintain.
A faucet flow valve and a method for operating a faucet flow valve are described. In one example, a faucet flow valve and a method for operating a faucet flow valve allowed the valve to open with a relatively short movement. In another example, fluid flow is provided with a relatively short actuation movement for example with a actuator element. In another example, higher fluid flow can be achieved with a smaller amount of actuation movement.
In one example of a valve and method of operation, a valve closure element is positioned in a valve body and partially transverse to the valve body. Transverse orientation in some cases permits smaller packages for operation and installation, and also shorter movement for producing a given flow relative to other configurations. Transverse orientation also helps to reduce the effects of water pressure and flow on movement of valve parts. A bias at least partly within the valve body biases the valve closure element against a valve seat. An actuator is accessible from outside the valve body and configured to move the closure element. In one example, the actuator is positioned vertically relative to the valve, or generally parallel to a central axis of the valve. The actuator can also be oriented in other directions. The closure element can be moved directly, or through contact with a valve stem or other element in contact with or capable of contacting the closure element. The valve body can be mounted to a faucet outlet, having a faucet outlet axis, and the valve body can have an inlet, and the inlet may be offset from the faucet outlet axis. The valve body Inlet can be offset from a valve body outlet. The valve body can also have a flow path, and part of the flow path between an inlet and outlet can extend transversely of the valve body.
In another example of a valve and method of operation, a valve closure element is positioned in a valve body and partially transverse to the valve body, and biased toward a valve seat. The closure element may be positioned downstream from a valve flow inlet. In one example, the closure element can include a head portion and a body portion, and the head portion may be convex, conical, hemispherical or other geometry. The closure element can be biased by a spring, a coil spring, a spring having a conical profile, or other form of bias construction. The valve seat may include an O-ring, and may be located downstream of an inlet to the valve body. The inlet may be an opening to a passageway in the valve body, and the valve seat may be adjacent a downstream opening of the passageway. The valve seat includes a sealing surface, for example a surface of an O-ring, and a sealing surface or the sealing element may interrupt a line between the downstream opening of the passageway and an opening for a fluid flow path downstream from the valve seat. In a further example, the inlet passageway may have a maximum cross-sectional distance and the valve closure element can be moved for opening the valve at least or approximately half the maximum cross-sectional distance. For example, if the passageway were circular in cross-section, the valve closure element can be moved at least half of the diameter. In another example, the valve closure element can be moved at least or approximately one quarter of the cross-sectional distance. In another configuration, the closure element can be moved by a structure moving on a diameter of the valve body, and in another configuration the closure element can be moved by a structure moving off a diameter of the valve body.
In a further example of a valve and method of operation, a valve control element moves at least partially transversely of an incoming water flow path, and is biased in transversely against a valve seat. In one example, the control element can be moved by a transversely-oriented valve stem or other actuator element against the force of the bias. The control element can include a valve seat contacting portion, which portion may be convex, hemispherical, conical, or other geometries.
In another example of a valve and method of operating, a valve closure element can be moved at least partially transversely of an axis between the faucet outlet and an outlet of the valve body. The closure element may be moved against a bias, such as one biasing the closure element against a valve seat. An actuator element can be operated to move the closure element against the bias. The actuator element can include a valve stem, which may also move at least partially transversely of the axis. They actually are element can include a handle or other element pivoting relative to the valve body.
These and other examples are set forth more fully below in conjunction with drawings, a brief description of which follows.
This specification taken in conjunction with the drawings sets forth examples of apparatus and methods incorporating one or more aspects of the present inventions in such a manner that any person skilled in the art can make and use the inventions. The examples provide the best modes contemplated for carrying out the inventions, although it should be understood that various modifications can be accomplished within the parameters of the present inventions.
The benefits of the present examples will become more apparent with consideration of the description of the examples herein. However, it should be understood that not all of the benefits or features discussed with respect to a particular example must be incorporated into a valve, component or method in order to achieve one or more benefits contemplated by these examples. Additionally, it should be understood that features of the examples can be incorporated into a valve, component or method to achieve some measure of a given benefit even though the benefit may not be optimal compared to other possible configurations. For example, one or more benefits may not be optimized for a given configuration in order to achieve cost reductions, efficiencies or for other reasons known to the person settling on a particular product configuration or method.
Examples of a number of valve configurations and of methods of making and using the valves are described herein, and some have particular benefits in being used together. However, even though these apparatus and methods are considered together at this point, there is no requirement that they be combined, used together, or that one component or method be used with any other component or method, or combination. Additionally, it will be understood that a given component or method could be combined with other structures or methods not expressly discussed herein while still achieving desirable results.
It should be understood that terminology used for orientation, such as front, rear, side, left and right, upper and lower, and the like, are used herein merely for ease of understanding and reference, and are not used as exclusive terms for the structures being described and illustrated.
The present valve configuration can be used with a number of flow configurations. The valve configuration is relatively compact, requires little effort to operate, and can use a variety of component designs without significantly affecting water pressure or flow. While the present valve configuration can be used in a number of applications, the present description will focus on its use in conjunction with a home faucet, such as for a sink, for example kitchen or bathroom sinks. However, it should be understood that the valve configuration can be used in a variety of other fluid flow applications.
In one configuration, a valve 100 for use with a faucet, such as the faucet 102 generically represented in
In the present examples, the aerator 108 is a conventional aerator assembly. The aerator may be threaded onto a lower portion of the valve body 106, for example using complementary threads, in a manner well known in the art.
The swivel ring 114 (
The valve and swivel ring are assembled by placing the swivel ring over the adjacent end of the valve. The tolerances between the valve and the swivel ring are such that the outside surface of the valve adjacent to the swivel ring biases the spring clip 124 outward and deeper into the annular groove 122 so that the swivel ring and the spring clip can pass over the outside adjacent surface of the valve. When the spring clip 124 reaches a complementary groove 156 in the valve, part of the spring clip enters the groove 156 and substantially locks the valve and swivel ring axially. In one configuration, the spring clip can be normally biased outward into the swivel ring, and the spring clip and swivel ring mounted on to the valve. In another configuration, the spring clip can be biased outward and positioned on the valve in the groove 156, and then pressed inward into the groove 156 as the swivel ring 114 passes over the spring clip. The spring clip then relaxes outwardly into the groove 122 to lock the two axially. The valve easily pivots or rotates relative to the swivel ring. Other configurations are possible.
With the swivel ring 114 as shown and having internal and external threads on the upper cylindrical wall at 116 and 118, the valve can be positioned on a faucet having either male or female threads. The swivel permits the valve to be oriented in the desired configuration about a central spout axis extending through the swivel ring, the valve and the aerator 108 (as viewed in
Once the valve is assembled onto the faucet, such as faucet 102, the conventional valves incorporated into the faucet are configured to provide the desired flow volume and temperature during normal operation. The conventional valves can then be left in the selected configurations and the valve 100 used to operate the faucet and turn the flow on and off.
The lever 104 of the present valve is positioned on a side of the valve body 106, and in the present example has a portion, such as an actuator end portion 126, that is aligned with a diameter of the valve body. The lever 104 includes the actuator end portion within a groove or slot 128 on the outside of the valve body on a side of a pivot pin 130 opposite the lever arm which is accessible to the user for operating the valve. The pivot pin 130 extends through openings 132 (
A locking arm 138 pivots about a pivot pin 140 relative to the lever 104. The pivot pin 140 extends through openings 142 and 144 (
Considering the valve in more detail and its internal components (
The valve body includes an upper surface 150 into which extends an inlet 152. In the present examples, the inlet is formed as a circular opening on an axis spaced apart from a central axis of the valve and a central axis of the faucet outlet opening, extending vertically as viewed in
The inlet 152 extends completely through a wall of the valve body 106 from the upper surface to a counter bore 158 formed concentric with the central bore 146. The counter bore 158 is formed in and extends from the outside wall of the valve body to an annular base wall 160, which defines an opening 162 into the bore 146 (
In the present example, the axis of the inlet 152 will intersect the diameter that forms the axis for the central bore 146. However, it should be understood that the inlet 152 can be off center relative to the central axis of the central bore. However, it is desirable to ensure that the inlet 152 flows into the counter bore upstream from the seal element, O-ring 164, in the valve. It is also desirable in one configuration of the valve assembly to have the inlet 152 positioned relatively close to the seal element 164, without interfering with the integrity of the seal or valve seat. The relative position of the inlet 152 can be used to reduce the amount of incoming water that impacts or contacts the closure element. In the present examples, the central bore 146 is substantially right circular cylindrical, and the counter bore 158 is also substantially right circular cylindrical. The counter bore extends from an outside surface of the valve body to the bottom surface 160 internal to the valve body.
An entrance portion of the counter bore 158 is internally threaded for receiving a retaining and closing cap 166 having complimentary threads. The cap closes counter bore and also keeps water from flowing from the valve out the opening of the counter bore. The cap also retains the biased closure element, described more fully below. The cap may include a slot or other configuration for installing the removing the cap.
The bottom or base surface 160 of the counter bore 158 surrounds and defines the opening to the central bore 146 and forms a base or seat against which the O-ring 164 is to be seated. The internal diameter of the counter bore is preferably slightly smaller than the relaxed outer diameter of the O-ring 164 to form a good seal between the counter bore and the O-ring. The bottom surface of the counter bore in the present examples is positioned axially along the diameter of the central bore between the threads for the cap 166 and the central vertical axis of the valve body.
The central bore 146 extends from the bottom of the counter bore 158 along the diameter to an opening 168 facing the actuating end portion 126 of the lever 104. In the present example, therefore, the central bore extends completely through the valve body on a diameter.
An outlet 168 extends from the central bore 146 to a lower surface 170 of the valve body 106. The outlet 168 in the present examples is a bore 172 (
A substantially cylindrical wall 174 extends downwardly as viewed in
Other moving portions of the valve besides the lever 104 include the valve stem or pushrod 148 extending within the central bore 146. The right end or anvil portion 175 of the valve stem (as viewed in
A valve element or closure element 178 contacts and rests against the valve seat, in the present example the O-ring seal 164, under the bias of a coil spring 180 positioned between the valve element 178 and the cap 166. The spring 180 is sized to fit within a bore in the cap 166 and around a reduced diameter shaft of the valve element 178. The head of the valve element in the present examples is rounded similar to a hemisphere. In the present example, the valve element 178 includes a head portion 182 and a body portion 184. The head portion contacts the valve seat to close the valve. The head portion is also contacted by the valve stem 148 in order to allow opening of the valve through the lever 104. In the present example, the head portion has a convex configuration or geometry, and includes a relatively flat portion in the center where the head portion is contacted by the valve stem 148. The convex geometry follows a substantially circular profile to the proximal end of the head portion, where it meets the body portion 184. In one example, the head portion is substantially circular in transverse cross-section and has a maximum dimension, in the present example a diameter, greater than the inside diameter of the O-ring 164 and less than the outside diameter of the O-ring. In one example, the cross-sectional thickness of the O-ring is X, and the diameter of the head portion is approximately the inside diameter of the O-ring plus one half X. In another example, the head portion diameter is less than the inside diameter of the O-ring plus one half X and in another example is greater than the inside diameter of the O-ring plus one half X. The head portion diameter may be selected as a function of the stability of the valve element 178 during operation, the size or diameter of the body portion 184 and the diameter of the spring or other bias and how the spring contacts the underside of the head portion. With a larger body portion diameter and spring diameter, the movement of the valve element can be more stable. The head portion can take other configurations as well, including for example but not by way of limitation those described herein.
The body portion 184 of the valve element 178 has a length sufficient to allow the valve element to be reliably positioned in the counter bore 158 with the spring 180 biasing the valve element against the valve seat. The length can be selected so as to accommodate the expected travel of the valve stem 148 without contacting the cap 166. Alternatively, the length can be selected so that the valve element contacts the cap 166 when the valve is opened, thereby stopping the travel of the valve stem 148. The diameter of the body portion can be selected to be slightly less than the inside diameter of the spring 180, for example so that the valve element does not move appreciably within the spring envelope. The body portion diameter can be significantly less than the inside diameter of the spring, if desired.
The distal end of the spring 180 bears against the proximal portion of the valve element head portion, and biases the valve element into the valve seat and toward the left end of the valve stem 148. The spring 180 is a conventional coil compression spring. The spring is selected so as to allow relatively easy opening of the valve while still being strong enough to reliably bias the valve element against the valve seat and securely close the valve against leakage. The coil spring diameter can be selected large enough to reduce any tendency of the coil spring and/or valve element to bend away from their normal axis. A further consideration for the coil spring diameter includes reliably positioning the coil spring in the cap 166 without allowing appreciable lateral movement of the spring. Another consideration for the coil spring diameter is to have the spring reliably contact the underside of the head portion 182 and reliably seat against the O-ring 164. In other configurations, the coil spring can have a conical configuration, or the spring can be a leaf spring, helical spring or other bias configuration. The spring configuration can also be selected as a function of the valve element configuration.
In operation, the lever 104 is pushed backward, in the present examples, or to the right in
The horizontal arrangement or flow-transverse arrangement of the valve assembly and components within the valve body 106 allow very short travel distances for the valve stem to open the valve. The valve stem, for example, and the valve seat, are oriented transverse to the water flow inlet to the valve body and transverse to the water flow out of the aerator. Similarly, a relatively short travel distance for the actuator end of the lever 104 permits easy actuation of the valve for full flow with a relatively short travel distance. Additionally, depending on the position and configuration of the valve sealing arrangement, such as the valve seat and valve element 178, fluid flow past the valve seat can be improved over other configurations.
The valve seat can take a number of configurations to achieve the closure or sealing function provided by the O-ring and the valve closure. For example, as represented in
The valve can also be designed to minimize the impediment to flow presented by the valve element 178. For example, the head portion 182 of the valve element can be configured to produce a small side profile when viewed from the direction of the inlet 152. For example, a valve element 188 (
In another example, a valve element 196 (
In a further example, a valve assembly 300 (
Valves according to the present examples can be easily installed on conventional faucets, including those used in kitchens, bathrooms, and the like. The lever can be easily activated with the user's hand, wrist, arm or other element for starting the flow. Additionally, the valve can be made smaller than conventional valves and used on smaller faucets such as small bathroom faucets. The valves can eliminate the constant use of the conventional valves incorporated as part of the original faucet, and the conventional valves can remain open and set to the user's desired mixture of hot and cold water. This can also reduce the wear on the conventional valves. The threads and the adapter can be used to permit the valve to be installed on almost any kitchen or bathroom faucet, and a swiveling adapter can be used, if desired, to position the valve and lever 104 in the desired position. The valves can also be used on dispensers such as drinking water dispensers and the like. The valves also improve hygiene, and improve conservation.
In other examples, a coil spring in the shape of a cone can be used to help center the valve element. In further examples, the valve element can have a conical head, with or without a valve body about which the bias spring can extend. Additionally, with any of the valve elements described herein, the valve seat or base of the counter bore can take a number of configurations, including flat as shown in the Figures, rounded in cross-section to conform to the surface of an O-ring as shown in
Having thus described several exemplary implementations, it will be apparent that various alterations and modifications can be made without departing from the concepts discussed herein. Such alterations and modifications, though not expressly described above, are nonetheless intended and implied to be within the spirit and scope of the inventions. Accordingly, the foregoing description is intended to be illustrative only.
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US8757210 *||Apr 2, 2012||Jun 24, 2014||Globe Union Industrial Corp.||Constant temperature outlet structure|
|U.S. Classification||137/1, 137/801, 251/231|
|International Classification||F16K21/00, F16K31/44, E03B1/00|
|Cooperative Classification||F16K23/00, Y10T137/9464, F16K1/12, E03C1/08, Y10T137/0318|
|European Classification||F16K1/12, E03C1/08, F16K23/00|